RFID Portal Array Antenna System
This invention provides an array antenna for a radio frequency identification (RFID) system, the array antenna comprises a transmission line with a longitudinal span proximately equaling to a height of a space desired to be covered by the array antenna, the transmission line having a terminal coupled to a RFID reader, and a plurality of radiating elements disposed on the first transmission line along the longitudinal span, additionally, reflective materials used behind the array antenna to maximize the illumination in the desired space and absorptive materials installed surrounding the desired space, in order to minimize the illumination of the undesired space surrounding the desired space.
The present application claims the benefits of U.S. Provisional Application Ser. No. 60/808,897, which was filed on May 26, 2006. There are also two co-pending application Ser. Nos. 11/690,562, filed Mar. 23, 2007, and 11/750,307, filed on May 17, 2007, which are incorporated by reference in its entirety.
BACKGROUNDThe present invention relates generally to radio frequency identification (RFID) antennas, and more specifically, to RFID antennas arranged in arrays.
A RFID system uses radio frequency transmission to identify, categorize, locate and track objects. The RFID system comprises two primary components: a transponder or the RFID tag and a reader. The tag is a device that generates electrical signals or pulses interpreted by the reader. The reader is a transmitter/receiver combination (transceiver) that activates and reads the identification signals from the transponder. The RFID tags are attached to objects that need to be tracked, and can be programmed to broadcast a specific stream of data denoting the object's identity, such as serial and model numbers, price, inventory code and date. A reader will detect the “tagged” object and further connects to a large network that will send information on the objects to interested parties such as retailers and product manufacturers. The RFID tags are considered to be intelligent bar codes that can communicate with a networked system to track every object associated with a designated tag. Therefore, the RFID tags are expected to be widely used in supply chain management, such as tracking shipping and handling. In such supply chain management applications, merchandize are often packed in pallets or large piles of containers. Conventional horn antennas have been used in such supply chain management applications.
In view of the above applications, there is clearly a need to develop a RFID antenna system that facilitates reading 100% of the tagged items in a desired object space, and 0% in undesired spaces. If a pallet is the desired object space, then any space outside of the pallet is the undesired space.
SUMMARYThis invention provides an array antenna for a radio frequency identification (RFID) system. According to a first embodiment of the present invention, the array antenna comprises a transmission line with a longitudinal span proximately equaling to a height of a space desired to be covered by the array antenna, the transmission line having a terminal coupled to a RFID reader, and a plurality of radiating elements disposed on the first transmission line along the longitudinal span, wherein the desired space is proximately evenly covered by radiations from the plurality of radiating elements.
According to a second embodiment of the present invention the array antenna comprises a first transmission line with a first longitudinal span proximately equaling to a height of a space desired to be covered by the array antenna, a first plurality of radiating elements disposed on the first transmission line along the first longitudinal span, a second transmission line having a second longitudinal span also proximately equaling to the height of the desired space, the second transmission line being substantially parallel to the first transmission line, yet separated from the first transmission line by a first predetermined distance in a horizontal direction, and a second plurality of radiating elements disposed on the second transmission line along the second longitudinal span, vertically adjacent radiating elements of both the first and second plurality of radiating elements being separated by at least one second predetermined distance in the vertical direction, wherein the desired space is proximately evenly covered by radiations from both the first and second plurality of radiating elements.
According to a third embodiment of the present invention, the antenna system of the second embodiment is mounted near absorptive panels that are used to attenuate the undesired radiations from the antenna system and the scattering from the pallet illuminating nearby tagged items that are not located on the pallet being interrogated by the antenna system.
According to a fourth embodiment of the present invention, the absorptive panels described earlier should not be placed directly next to the antenna system because it will impact its radiation performance, a conducting panel should be placed directly behind the antennas to re-direct the antenna back radiation toward the pallet being measured.
The construction and method of operation of the invention, however, together with additional objects and advantages thereof will be best understood from the following description of specific embodiments when read in connection with the accompanying drawings.
The drawings accompanying and forming part of this specification are included to depict certain aspects of the invention. A clearer conception of the invention, and of the components and operation of systems provided with the invention, will become more readily apparent by referring to the exemplary, and therefore non-limiting, embodiments illustrated in the drawings, wherein like reference numbers (if they occur in more than one view) designate the same elements. The invention may be better understood by reference to one or more of these drawings in combination with the description presented herein. It should be noted that the features illustrated in the drawings are not necessarily drawn to scale.
The present invention provides a RFID array antenna system that has good selective coverage, i.e., a complete coverage in a desired space, and very little coverage in spaces outside the desired space.
A RFID system is a backscatter system, in which signals transmitted to a RFID tag, being modulated thereby, and then scattered back to a reader antenna. The transmission power is greatly attenuated during propagating to and from the tag antenna without even considering the additional loss associated with the tag antenna efficiency in creating the modulation. As a result, the backscattered signal is extremely weak. Therefore, a RFID reader needs to radiate significant power and has to have a very low-noise receiver to provide an adequate dynamic range. In order to improve the system signal-to-noise ratio, the present invention proposes to use multiple independent ports, including respective antennas, for the RFID system. Having multiple independent RFID antenna ports is clearly superior to the conventional single port antenna RFID reader system.
Each array, 320 or 330, of the antenna system 310 may be constructed in the same way as the shelf antenna disclosed by Burnside et al., also inventors of the present invention, in a U.S. patent application Ser. No. 11/750,307, filed on May 17, 2007. The radiating elements of the array antenna may be protruding conductive strips coupled to a top plate of the distributed antenna. The coupling between the conductive strips and the top plate may be accomplished through a direct electrical connection, capacitive coupling or inductive coupling. Skilled artisan may also appreciate conductive patches or conductive loops may also serve as the radiating elements. The conductive patches or the conductive loops may be coupled to the top plate by electrical connection, capacitive coupling or inductive coupling.
In another application, two RFID reader antenna systems are used to interrogate a pile of containers. One reader antenna system is located on either side of the pile or even on the top and bottom of the pile as well. These antenna systems can be connected to the RFID reader system through different ports. As a result, these multiple antenna systems can interrogate different sides of the pile as it passes by these antennas. This will greatly improve the illumination of all sides of the pile and provide much higher read rates for the tagged items located within the pile.
As stated earlier, there can be significant interference between closely-spaced RFID reader systems. Yet, in another application, identical RFID readers of different networks may be placed close to each other. For instance, adjacent warehouse doorways may have identical RFID systems. Since these doorways are very close together, one must isolate these multiple systems from interferences between adjacent RFID readers as well as undesired reflections from containers. Especially considering that the reflections from containers are often times uncontrollable. As a result, the present invention proposes to integrate some absorptive material close to the antenna array, so that much of the reflected signals will be absorbed before reaching the adjacent reader antenna system.
A RFID portal system is a special kind of RFID pallet reader system in which the RFID reader is stationed in a doorway, for instance. The RFID portal system performs a read when a pallet passes through the RFID portal system. A design goal is, apparently, to fully read all the tagged items contained within the pallet, and read nothing outside of the pallet. The array antenna system 400 of
The desired signal directly illuminates the pallet, which is located right in front of the reader antenna of such a portal system. Since the radiation level of the portal system is limited by regulatory agencies, the presence of the absorptive panels will inevitably lower the desired signal level as well. In order to alleviate such a negative effect, the absorptive panels should be disposed not in the immediate surroundings of the portal array antenna. In fact, it is the best if the portal reader antenna is mounted in front of a reflective metal panel so that a back radiation from the portal reader antenna is reflected toward the pallet to enhance the illumination of the pallet.
The portal structure 500 as shown in
Since this portal structure must be able to withstand bumpy situations associated with such warehouse applications, the whole structure must be made very durable to sustain outside impacts. As shown in
In a typical warehouse application, the portal antenna structure 700 may be on the order of 4″ to 5″ thick, 5′ to 12′ tall and 3′ to 10′ wide. Because of materials used in its construction, it will be a relatively light-weight structure considering its size. It can be permanently mounted onto a fixed structure or installed on wheels for being easily moved around. The portal structure 500 that is built from the portal antenna panel 700 may have sensors for detecting an approaching or a leaving of a pallet. These sensors are used to control a reader system of the portal structure so that the reader system only reads tagged items within the pallet during the time that the pallet is within the portal structure. This is necessary because a pallet outside the portal will tend to scatter the RFID signal around the surrounding area and again create a significant environmental tag clutter, which is not acceptable. The portal sensor signals can be directly input to the reader system or to a system control computer. In either case, the reader is basically cleared of all tagged items before the pallet enters the portal. It then reads the tagged items until the pallet leaves the portal. In this way, the portal reader system focuses on tagged items within the pallet and minimizes false reads of tagged items disposed in the near vicinity of the portal structure but not on the pallet. Using this approach, the proposed portal structure is able to provide nearly 100% reads of the pallet tagged items and minimal reads of the tagged items not found on the pallet, which is the objective of this design.
The above illustrations provide many different embodiments or embodiments for implementing different features of the invention. Specific embodiments of components and processes are described to help clarify the invention. These are, of course, merely embodiments and are not intended to limit the invention from that described in the claims.
Although the invention is illustrated and described herein as embodied in one or more specific examples, it is nevertheless not intended to be limited to the details shown, since various modifications and structural changes may be made therein without departing from the spirit of the invention and within the scope and range of equivalents of the claims. Accordingly, it is appropriate that the appended claims be construed broadly and in a manner consistent with the scope of the invention, as set forth in the following claims.
Claims
1. An array antenna for a radio frequency identification (RFID) system, the array antenna comprising:
- a first transmission line with a first longitudinal span proximately equaling to a height of a space desired to be covered by the array antenna, the first transmission line having a first terminal coupled to a RFID reader; and
- a first plurality of radiating elements disposed on the first transmission line along the first longitudinal span,
- wherein the desired space is covered by one or more proximately plane wave radio frequency (RF) signals transmitted from the plurality of radiating elements.
2. The array antenna of claim 1, wherein the first transmission line comprises a first and second plate, the first plate being disposed closer to the desired space than the second plate, wherein the first plurality of radiating elements are disposed on the first plate.
3. The array antenna of claim 2 further comprising a third plate substantially wider than the first and second plate, the third plate being disposed farther away from the desired space than the first and second plates, wherein backward radiations from the first plurality of radiating elements are reflected into the desired space by the third plate.
4. The array antenna of claim 3, wherein the third plate is made of one piece of one or more conductive materials.
5. The array antenna of claim 2, wherein the first plurality of radiating elements are protruding conductive strips coupled to the first plate, the coupling between the conductive strips and the first plate consisting of the group selected from electrical connection, capacitive coupling and inductive coupling.
6. The array antenna of claim 2, wherein the first plurality of radiating elements are conductive patches coupled to the first plate, the coupling between the conductive patches and the first plate consisting of the group selected from electrical connection, capacitive coupling and inductive coupling.
7. The array antenna of claim 2, wherein the first plurality of radiating elements are conductive loops coupled to the first plate, the coupling between the conductive loops and the first plate consisting of the group selected from electrical connection, capacitive coupling and inductive coupling.
8. The array antenna of claim 2, wherein the first plurality of radiating elements are cut-outs from the first plate, the cut-outs consisting of the group selected from slots, notches and recesses.
9. The array antenna of claim 1, the first plurality of radiating elements radiates in one or more predetermined polarization angles.
10. The array antenna of claim 9, wherein the one or more predetermined polarization angles are 45°.
11. The array antenna of claim 9, wherein the one or more predetermined polarization angles comprise a pair of cross-polarized angles.
12. The array antenna of claim 1, wherein the first plurality of radiating elements have different dimensions for achieving uniform radiations from the first plurality of radiating elements.
13. The array antenna of claim 1 further comprising:
- a second transmission line with a second longitudinal span proximately equaling to the height of the desired space, the second transmission line having a second terminal also coupled to the RFID reader, the second transmission line being substantially parallel to, yet separated from the first transmission line by a first predetermined distance in a horizontal direction; and
- a second plurality of radiating elements disposed on the second transmission line along the second longitudinal span, vertically adjacent radiating elements of both the first and second plurality of radiating elements being separated by at least one second predetermined distance in the vertical direction.
14. The array antenna of claim 13, wherein the first and second predetermined distances are less than a wavelength of an operating RFID signal.
15. The array antenna of claim 13, wherein the first transmission line is coupled to a first port of the RFID reader and the second transmission line is coupled to a second port of the same RFID reader.
16. The array antenna of claim 13, wherein the first and second plurality of radiating elements have cross-polarized radiations.
17. The array antenna of claim 1 further comprising at least one radio frequency (RF) energy absorptive panel disposed surrounding the desired space.
18. The array antenna of claim 17, wherein the RF energy absorptive panel is disposed substantially behind the first transmission line away from the desired space.
19. The array antenna of claim 17, wherein the RF energy absorptive panel comprises a plurality of separated resistive layers.
20. The array antenna of claim 19, wherein the plurality of separated resistive layers are kept apart by low RF energy loss materials.
21. An array antenna for a radio frequency identification (RFID) system, the array antenna comprising:
- a first transmission line with a first longitudinal span proximately equaling to a height of a space desired to be covered by the array antenna;
- a first plurality of radiating elements disposed on the first transmission line along the first longitudinal span;
- a second transmission line having a second longitudinal span also proximately equaling to the height of the desired space, the second transmission line being substantially parallel to the first transmission line, yet separated from the first transmission line by a first predetermined distance in a horizontal direction; and
- a second plurality of radiating elements disposed on the second transmission line along the second longitudinal span, vertically adjacent radiating elements of both the first and second plurality of radiating elements being separated by at least one second predetermined distance in the vertical direction,
- wherein the desired space is covered by one or more proximately plane wave radio frequency (RF) signals transmitted from the plurality of radiating elements.
22. The array antenna of claim 21, wherein
- the first transmission line comprises a first and second plate, the first plate being disposed closer to the desired space than the second plate, wherein the first plurality of radiating elements are disposed on the first plate;
- the second transmission line comprises a third and fourth plate, the third plate being disposed closer to the desired space than the fourth plate, wherein the second plurality of radiating elements are disposed on the third plate.
23. The array antenna of claim 22 further comprising a fifth and sixth plates, the fifth plate being substantially wider than the first and second plates, the fifth plate being disposed farther away from the desired space than the first and second plates, wherein backward radiations from the first plurality of radiating elements are reflected into the desired space by the fifth plate, and the sixth plate being substantially wider than the third and fourth plates, the sixth plate being disposed farther away from the desired space than the third and fourth plates, wherein backward radiations from the second plurality of radiating elements are reflected into the desired space by the sixth plate.
24. The array antenna of claim 23, wherein the fifth and sixth plate are made of one piece of one or more conductive materials.
25. The array antenna of claim 24 further comprising at least one RF energy absorptive panel disposed on the one piece of one or more conductor materials towards the desired space but exposing the conductor in the close vicinity of the first and second transmission lines.
26. The array antenna of claim 21, wherein the first and second predetermined distances are less than a wavelength of an operating RFID signal.
27. The array antenna of claim 21, wherein the first transmission line is coupled to a first port of a RFID reader and the second transmission line is coupled to a second port of the RFID reader.
28. The array antenna of claim 21, wherein the first and second plurality of radiating elements have cross-polarized radiations.
29. The array antenna of claim 21 further comprising at least one radio frequency (RF) energy absorptive panel disposed surrounding the desired space.
30. The array antenna of claim 29, wherein the RF energy absorptive panel is disposed substantially behind the first and second transmission lines away from the desired space.
31. The array antenna of claim 29, wherein the RF energy absorptive panel comprises a plurality of resistive layers being separated by low RF energy loss materials.
32. An array antenna for a radio frequency identification (RFID) system, the array antenna comprising:
- a first transmission line with a first longitudinal span proximately equaling to a height of a space desired to be covered by the array antenna, the first transmission line being coupled to a first port of a RFID reader;
- a first plurality of radiating elements disposed on the first transmission line along the first longitudinal span;
- a second transmission line having a second longitudinal span also proximately equaling to the height of the desired space, the second transmission line being substantially parallel to the first transmission line, yet separated from the first transmission line by a first predetermined distance in a horizontal direction, the second transmission line being coupled to a second port of the RFID reader; and
- a second plurality of radiating elements disposed on the second transmission line along the second longitudinal span, vertically adjacent radiating elements of both the first and second plurality of radiating elements being separated by at least one second predetermined distance in the vertical direction,
- wherein the desired space is covered by one or more proximately plane wave radio frequency (RF) signals transmitted from the plurality of radiating elements.
33. The array antenna of claim 32, wherein
- the first transmission line comprises a first and second plate, the first plate being disposed closer to the desired space than the second plate, wherein the first plurality of radiating elements are disposed on the first plate;
- the second transmission line comprises a third and fourth plate, the third plate being disposed closer to the desired space than the fourth plate, wherein the second plurality of radiating elements are disposed on the third plate.
34. The array antenna of claim 32, wherein the first and second transmission lines are mounted above a ground plane, the ground plane being made of one piece of one or more conductive materials and substantially wider than the area occupied by the first and second transmission lines and the ground plane being positioned farther away from the desired space than the first and second transmission lines, wherein backward radiations from the first and second pluralities of radiating elements are reflected into the desired space by the ground plane.
35. The array antenna of claim 34 further comprising at least one RF energy absorptive panel disposed on the ground plane toward the desired space but exposing the ground plane in the close vicinity of the first and second transmission lines.
36. The array antenna of claim 32, wherein the first and second predetermined distances are less than a wavelength of an operating RFID signal.
37. The array antenna of claim 32, wherein the first and second plurality of radiating elements have cross-polarized radiations.
38. The array antenna of claim 32 further comprising at least one radio frequency (RF) energy absorptive panel disposed surrounding the desired space.
39. The array antenna of claim 38, wherein the RF energy absorptive panel is disposed substantially behind the first and second transmission lines away from the desired space.
40. The array antenna of claim 38, wherein the RF energy absorptive panel comprises a plurality of resistive layers being separated by low RF energy loss materials.
Type: Application
Filed: May 24, 2007
Publication Date: Nov 29, 2007
Patent Grant number: 7528726
Inventors: Teh-Hong Lee (Dublin, OH), Walter D. Burnside (Dublin, OH), Robert J. Burkholder (Columbus, OH), Chan-Ping Edwin Lim (Hilliard, OH)
Application Number: 11/753,487
International Classification: G08B 13/14 (20060101); H04Q 5/22 (20060101);